MRI‐based quantitative susceptibility mapping (QSM) and R2* mapping of liver iron overload: Comparison with SQUID‐based biomagnetic liver susceptometry

Sharma, Samir D.; Fischer, Roland; Schoennagel, Bjoern P.; Nielsen, Peter; Kooijman, Hendrik; Yamamura, Jin; Adam, Gerhard; Bannas, Peter; Hernando, Diego; Reeder, Scott B.

doi:10.1002/mrm.26358

Cited by 65 publications

(117 citation statements)

References 38 publications

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“…Fortunately, QSM has a simple linear relationship with these intravoxel contents according to chemical decomposition, allowing linear extraction of iron content. Furthermore, except fat (quantifiable according to its chemical shifts and phase data (45)), other intravoxel contents, including fibrosis and edema, have a susceptibility that is virtually zero relative to water, making QSM ideally suited for determining the iron concentration of liver, heart, and other tissues (45,187) (Fig. 11).…”

Section: Clinical Applications Enabled By Qsm Biometal Imagingmentioning

confidence: 99%

Clinical quantitative susceptibility mapping (QSM): Biometal imaging and its emerging roles in patient care

Wang

Spincemaille

Liu

et al. 2017

Magnetic Resonance Imaging

215

199

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Quantitative susceptibility mapping (QSM) has enabled MRI of tissue magnetic susceptibility to advance from simple qualitative detection of hypointense blooming artifacts to precise quantitative measurement of spatial biodistributions. QSM technology may be regarded to be sufficiently developed and validated to warrant wide dissemination for clinical applications of imaging isotropic susceptibility, which is dominated by metals in tissue, including iron and calcium. These biometals are highly regulated as vital participants in normal cellular biochemistry, and their dysregulations are manifested in a variety of pathologic processes. Therefore, QSM can be used to assess important tissue functions and disease. To facilitate QSM clinical translation, this review aims to organize pertinent information for implementing a robust automated QSM technique in routine MRI practice and to summarize available knowledge on diseases for which QSM can be used to improve patient care. In brief, QSM can be generated with postprocessing whenever gradient echo MRI is performed. QSM can be useful for diseases that involve neurodegeneration, inflammation, hemorrhage, abnormal oxygen consumption, substantial alterations in highly paramagnetic cellular iron, bone mineralization, or pathologic calcification; and for all disorders in which MRI diagnosis or surveillance requires contrast agent injection. Clinicians may consider integrating QSM into their routine imaging practices by including gradient echo sequences in all relevant MRI protocols.

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Section: Clinical Applications Enabled By Qsm Biometal Imagingmentioning

confidence: 99%

Clinical quantitative susceptibility mapping (QSM): Biometal imaging and its emerging roles in patient care

Wang

Spincemaille

Liu

et al. 2017

Magnetic Resonance Imaging

215

199

View full text Add to dashboard Cite

show abstract

“…From its initial applications to endogenous brain iron quantification, quantitative susceptibility mapping (QSM) has seen increasing applications to a wide range of quantitative research on disease conditions including intracerebral hemorrhage, liver iron overload, bone mineral quantification, and preclinical contrast agent toxicity studies . These applications require confidence in the reproducibility of QSM for a wider range of susceptibility values, field strengths, and vendor platforms than has been previously reported by researchers …”

Section: Introductionmentioning

confidence: 99%

Multicenter reproducibility of quantitative susceptibility mapping in a gadolinium phantom using MEDI+0 automatic zero referencing

Deh

Kawaji

Bulk

et al. 2018

Magnetic Resonance in Med

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Purpose To determine the reproducibility of quantitative susceptibility mapping at multiple sites on clinical and preclinical scanners (1.5 T, 3 T, 7 T, and 9.4 T) from different vendors (Siemens, GE, Philips, and Bruker) for standardization of multicenter studies. Methods Seven phantoms distributed from the core site, each containing 5 compartments with gadolinium solutions with fixed concentrations between 0.625 mM and 10 mM. Multi‐echo gradient echo scans were performed at 1.5 T, 3 T, 7 T, and 9.4 T on 12 clinical and 3 preclinical scanners. DICOM images from the scans were processed into quantitative susceptibility maps using the Laplacian boundary value (LBV) and MEDI+0 automatic uniform reference algorithm. Region of interest (ROI) analyses were performed by a physicist to determine agreement between results from all sites. Measurement reproducibility was assessed using regression, Bland‐Altman plots, and the intra‐class correlation coefficient (ICC). Results Quantitative susceptibility mapping (QSM) from all scanners had similar, artifact‐free visual appearance. Regression analysis showed a linear relationship between gadolinium concentrations and average QSM measurements for all phantoms (y = 350x – 0.0346, r2>0.99). The SD of measurements increased almost linearly from 32 ppb to 230 ppb as the measured susceptibility increased from 0.26 ppm to 3.56 ppm. A Bland‐Altman plot showed the bias, upper, and lower limits of agreement for all comparisons were −10, −210, and 200 ppb, respectively. The ICC was 0.991 with a 95% CI (0.973, 0.99). Conclusions QSM shows excellent multicenter reproducibility for a large range of susceptibility values encountered in cranial and extra‐cranial applications on a diverse set of scanner platforms.

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“…Magnetic susceptibility is an inherent property of tissues that, unlike

{normalR}_{2}^{*}

, is independent of the magnetic field strength and, similar to

{normalR}_{2}^{*}

, increases with increasing LIC. Superconducting quantum interference devices are able to accurately measure magnetic susceptibility in the liver, and LIC quantification using these devices has been shown to correlate well with biopsy LIC measurements . However, the operation of these devices is expensive, and their availability is extremely limited.…”

Section: Introductionmentioning

confidence: 99%

Assessment of MR‐based and quantitative susceptibility mapping for the quantification of liver iron concentration in a mouse model at 7T

Simchick

Liu

Nagy

et al. 2018

Magnetic Resonance in Med

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The feasibility of quantifying LIC using MR-based R2* and QSM at a high field strength of 7T is demonstrated. Susceptibility quantification, which is an intrinsic property of tissues and benefits from being field-strength independent, is more robust than R2* quantification in this ex vivo study. A susceptibility-to-LIC conversion factor is presented that agrees relatively well with previously published QSM derived results obtained at 1.5T and 3T.

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MRI‐based quantitative susceptibility mapping (QSM) and R2* mapping of liver iron overload: Comparison with SQUID‐based biomagnetic liver susceptometry

Cited by 65 publications

References 38 publications

Clinical quantitative susceptibility mapping (QSM): Biometal imaging and its emerging roles in patient care

Clinical quantitative susceptibility mapping (QSM): Biometal imaging and its emerging roles in patient care

Multicenter reproducibility of quantitative susceptibility mapping in a gadolinium phantom using MEDI+0 automatic zero referencing

Assessment of MR‐based and quantitative susceptibility mapping for the quantification of liver iron concentration in a mouse model at 7T

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